Heat killing of bacterial spores analyzed by differential scanning calorimetry.

Thermograms of the exosporium-lacking dormant spores of Bacillus megaterium ATCC 33729, obtained by differential scanning calorimetry, showed three major irreversible endothermic transitions with peaks at 56, 100, and 114 degrees C and a major irreversible exothermic transition with a peak at 119 degrees C. The 114 degrees C transition was identified with coat proteins, and the 56 degrees C transition was identified with heat inactivation. Thermograms of the germinated spores and vegetative cells were much alike, including an endothermic transition attributable to DNA. The ascending part of the main endothermic 100 degrees C transition in the dormant-spore thermograms corresponded to a first-order reaction and was correlated with spore death; i.e., greater than 99.9% of the spores were killed when the transition peak was reached. The maximum death rate of the dormant spores during calorimetry, calculated from separately measured D and z values, occurred at temperatures above the 73 degrees C onset of thermal denaturation and was equivalent to the maximum inactivation rate calculated for the critical target. Most of the spore killing occurred before the release of most of the dipicolinic acid and other intraprotoplast materials. The exothermic 119 degrees C transition was a consequence of the endothermic 100 degrees C transition and probably represented the aggregation of intraprotoplast spore components. Taken together with prior evidence, the results suggest that a crucial protein is the rate-limiting primary target in the heat killing of dormant bacterial spores.

Occurrence of antibiotic and metal resistance and plasmids in Bacillus strains isolated from marine sediment.

Eleven hundred Bacillus strains isolated from marine sediment from the Minas Basin, Nova Scotia, Canada, were purified on LB agar supplemented with ampicillin, chloramphenicol, erythromycin, streptomycin, tetracycline, or mercuric chloride. Seventy-seven isolates were examined for plasmid DNA, and for resistance to 11 antibiotics, HgCl2, and phenylmercuric acetate. Minimum inhibitory concentrations of Ag, Cd, Co, Cu, and Zn were also determined. Forty-three percent of antibiotic- and mercury-resistant strains contained one or more plasmids ranging from 1.9 to 210 MDa. Fifty-four percent carried plasmids greater than 20 MDa, and 97% were resistant to two or more metals. There was no correlation between plasmid content and resistance either to antibiotics or to mercurial compounds in these strains. Mercury-resistant isolates were unable to transform Hg2+ to volatile Hg0 by virtue of a mercuric reductase enzyme system (mer). Strains resistant to Hg2+ were investigated for their ability to produce H2S and intracellular acid-labile sulfide when grown in the absence and presence of HgCl2. Lower levels of H2S and intracellular sulfide were detected only in metal-resistant strains grown in the presence of HgCl2, suggesting that cellular sulfides complexed with Hg2+ in these strains.

Heat Resistance Correlated with DNA Content in Bacillus megaterium Spores.

Two subpopulations of Bacillus megaterium spores (1.360 and 1.355 g/ml) were obtained by density gradient centrifugation. The heavier spores had a higher thermoresistance (e.g., D(80) = 186 versus 81 min) and a higher DNA content (1.25 x 10 versus 0.65 x 10 g per spore, apparently corresponding to digenomic versus monogenomic spores). No appreciable differences were found in the mineral and dipicolinic acid contents or in the inactivation kinetics of the two subpopulations. The implications of the findings are discussed with regard to mechanisms of heat resistance and of inactivation.

Mercury resistance determined by a self-transmissible plasmid in Bacillus cereus 5.

Inducible mercuric reductase activity in Bacillus cereus 5 was plasmid-encoded. Plasmid analysis revealed three plasmids with molecular masses of 2.6, 5.2 and 130 MDa. A mating system permitted transfer of the resistance determinant among strains of B. cereus and B. thuringiensis. Transfer of mercury resistance from B. cereus 5 to B. cereus 569 and B. thuringiensis occurred during mixed culture incubation on agar surfaces. The 130-MDa plasmid (pGB130) was responsible for transfer; frequencies ranged from 10(-5) to 10(-4). B. cereus 569 transconjugants inheriting pGB130 were also effective donors. High transfer frequencies and the finding that cell-free filtrates of donor cultures were ineffective in mediating transfer suggested mercury-resistance transfer was not phage-mediated. Transfer was also insensitive to DNase activity. Further evidence that pGB130 DNA carried the mercury-resistance determinant was transformation of B. cereus 569 by electroporation with pGB130 DNA isolated from B. cereus 5 and a mercury-resistant B. cereus 569 transconjugant. Mercury-resistant transconjugants and transformants exhibited mercuric reductase activity. Plasmid pGB130 also conferred resistance to phenylmercuric acetate.

Transformation of Bacillus cereus vegetative cells by electroporation.

Transformation of untreated vegetative cells of Bacillus cereus 569 with plasmid pC194 (1.8 megadaltons) by high-voltage electroporation resulted in a maximum of 2 x 10(-5) transformants per viable cell. Transformation of a 130-megadalton plasmid occurred at a comparable frequency. The method was simple, rapid, and yielded transformant colonies in 14 to 24 h. Transformation was obtained with unpurified total plasmid DNA.

Metal resistance and accumulation in bacteria.

Recent research on the ecology, physiology and genetics of metal resistance and accumulation in bacteria has significantly increased the basic understanding of microbiology in these areas. Research has clearly demonstrated the versatility of bacteria to cope with toxic metal ions. For example, certain strains of bacteria can efficiently efflux toxic ions such as cadmium, that normally exert an inhibitory effect on bacteria. Some bacteria such as Escherichia coli and Staphylococcus sp. can volatilize mercury via enzymatic transformations. It is also noteworthy that many of these resistance mechanisms are encoded on plasmids or transposons. By expanding the knowledge on metal-resistance and accumulation mechanisms in bacteria, it may be possible to utilize certain strains to recover precious metals such as gold and silver, or alternatively remove toxic metal ions from environments or products where their presence is undesirable.